An air situation information collecting device
By using a modular box structure and bolted connections, the air situation information acquisition equipment solves the problems of portability and stability of UAV information acquisition equipment in harsh environments, and achieves efficient information acquisition and processing.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 河北省国创京津冀科技发展有限公司
- Filing Date
- 2025-06-10
- Publication Date
- 2026-06-26
AI Technical Summary
Existing UAV information collection equipment is poorly portable in harsh environments, has a complex structure and scattered parts, making it difficult to efficiently collect and process information from low-altitude unmanned aerial vehicles.
The system employs a first and second assembly box structure to house the air situation information acquisition components and the information receiving and processing mechanism, respectively. These components are connected by bolts to form a portable integrated device. The device is equipped with heat dissipation and shielding structures to ensure stable operation in harsh environments.
It achieves portability and stability of the equipment in harsh environments, improves the efficiency of information collection and processing, facilitates disassembly and assembly, and adapts to different environmental needs.
Smart Images

Figure CN224417033U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of data acquisition equipment technology, and in particular to an air situation information acquisition device. Background Technology
[0002] The descriptions in this section provide background information relating to this disclosure and do not constitute prior art.
[0003] The widespread use of unmanned aerial vehicle (UAV) systems has greatly enriched people's daily lives and work across various industries. Drones initially intended for recreational purposes are increasingly being used for other uses. Technical methods to counter this type of drone threat include monitoring relevant signal spectrums, direction finding, and possible defensive countermeasures.
[0004] Related technologies use intelligent data acquisition devices to collect and monitor low-altitude flight conditions. In order to collect relatively comprehensive information on low-altitude unmanned aerial vehicles from the ground, intelligent data acquisition devices are usually complex in structure, including data acquisition parts, data optimization and processing parts, antennas, power supplies, etc. The dispersed carrying of various components makes them less portable and less mobile in the field when detecting the location of intruding low-altitude unmanned aerial vehicles in harsh environments such as high altitude, cold, and dense forests. Utility Model Content
[0005] The purpose of this utility model is to provide an air situation information acquisition device, which uses a first splicing box and a second splicing box to store relevant accessories separately. The first splicing box and the second splicing box are connected by a bolt connection structure, and the device forms a regular whole that is easy to carry and use in harsh environments.
[0006] This utility model provides an air situation information acquisition device, comprising:
[0007] The first assembly box contains air situation information acquisition components and a charging power supply in its internal cavity;
[0008] The second assembly box has an information receiving and processing mechanism installed in its internal cavity;
[0009] The first and second splicing boxes are stacked vertically, and the first and second splicing boxes are stacked vertically.
[0010] Bolted connections are installed between the assembled boxes;
[0011] When the air situation information acquisition component is used in conjunction with the information receiving and processing mechanism, the charging power supply is electrically connected to the air situation information acquisition component and the information receiving and processing mechanism, and the air situation information acquisition component and the information receiving and processing mechanism are communicatively connected.
[0012] As a further optimization, in order to shield and protect the information receiving and processing mechanism and provide necessary heat dissipation structure, the second splicing box includes:
[0013] The first storage compartment has a first slot in the middle of both its left and right side walls;
[0014] The first U-shaped cover has its two ends inserted into the first slots on both sides respectively;
[0015] The lower edge of the outer wall of the first slot is provided with a first reserved screw hole evenly distributed along the length direction;
[0016] The lower edges of the outer walls at both ends of the first U-shaped cover are provided with first connecting bolts that pass through the first reserved screw holes, and the ends of the bolts are screwed into the corresponding first reserved screw holes.
[0017] The outer wall of the first storage tank has a cable outlet hole corresponding to the interface of the information receiving and processing mechanism;
[0018] The side wall of the first storage slot where the cable outlet hole is located is equipped with a pull-out shielding structure.
[0019] The outer wall of the first storage tank is evenly covered with fish-scale heat dissipation holes.
[0020] As a further optimization, in order to shield the cable outlet hole on the outer wall of the first storage tank from dust, and to expose the cable outlet hole when needed, the pull-out shielding structure includes:
[0021] A strip-shaped groove is formed on the side wall of the outer wall of the first receiving groove where the wire outlet hole is located, and the strip-shaped groove is designed with an opening on one side;
[0022] A shielding strip is uniformly fixedly assembled along the length direction on the front side of the inner wall of the strip-shaped groove.
[0023] A strip baffle is slidably inserted between the strip groove and the rear wall of the shielding strip.
[0024] As a further optimization, in order to lock and position the information receiving and processing mechanism placed in the first storage slot and maintain its stability, a locking and positioning structure is installed between the bottom surface of the inner cavity of the first storage slot and the information receiving and processing mechanism.
[0025] A strip plate is fixedly assembled to the bottom surface of the inner cavity of the first storage tank;
[0026] A slot is provided on the upper edge of the outer wall of the strip plate near the information receiving and processing mechanism;
[0027] The information receiving and processing mechanism has a corresponding card block fixedly mounted on its outer wall in the corresponding card slot, and the card block is inserted into the slot.
[0028] Corresponding to the card slot.
[0029] As a further optimization, to ensure the stability of storage by separately attaching and fixing the switch and the micro-host, the switch receives information collected by the air situation information acquisition component and transmits the collected information to the micro-host for analysis and processing. The information receiving and processing mechanism includes:
[0030] The switch and the microcomputer are connected for communication.
[0031] The three strip panels are arranged in parallel, and the switch and the microcomputer are located in the gap between adjacent strip panels;
[0032] The outer walls of the switch and the micro-host are fixedly fitted with card blocks corresponding to the card slots of the adjacent strip plates.
[0033] As a further optimization, to facilitate the storage of the air situation information acquisition components and to allow for the disassembly of the first splicing box to remove and assemble the air situation information acquisition components when needed, the first splicing box includes:
[0034] The second storage compartment has a second slot in the middle of both its left and right side walls;
[0035] The second U-shaped cover has its two ends inserted into the second slots on both sides respectively;
[0036] The second slot has a second reserved screw hole evenly opened along its length on the lower edge of its outer wall;
[0037] The lower edges of the outer walls at both ends of the second U-shaped cover are provided with second connecting bolts that pass through the second reserved screw holes, and the ends of the bolts are screwed into the corresponding second reserved screw holes.
[0038] The air situation information acquisition component is located in the second storage tank.
[0039] As a further optimization, in order to collect low-altitude information on the ground using an antenna in conjunction with a miniature radar, the air situation information acquisition component includes:
[0040] A sponge pad is inserted into the second storage slot;
[0041] Miniature radar, antenna, and connecting cables;
[0042] The upper surface of the sponge pad has slots corresponding to the charging power supply, the miniature radar, the antenna, and the connecting cable, and the charging power supply, the miniature radar, the antenna, and the connecting cable are inserted into the corresponding slots.
[0043] The antenna is communicatively connected to the miniature radar via a connecting cable, and is also electrically connected to the charging power supply via the connecting cable.
[0044] As a further optimization, to facilitate the connection and fixation of the first and second splicing boxes, and to allow for easy disassembly when needed, the bolt connection structure includes:
[0045] A connecting groove is formed on the upper edge of the outer wall of the first splicing box;
[0046] The connecting plate, with its corresponding connecting groove, is fixedly connected to the edge of the bottom surface of the second splicing box.
[0047] The connecting plate is inserted into the connecting groove, and a third connecting bolt is screwed between the connecting plate and the bottom surface of the corresponding connecting groove.
[0048] As a further optimization, in order to facilitate carrying a screwdriver and disassembling the first connecting bolt, the second connecting bolt and the third connecting bolt, the outer wall of the second storage groove is provided with a threaded through hole, and the side wall of the sponge pad is provided with a blind hole corresponding to the threaded through hole.
[0049] The blind holes in the sponge pad are not connected to the slots;
[0050] A screwdriver is screwed into the threaded through hole, and its tip is inserted into the blind hole of the sponge pad.
[0051] As a further optimization, to facilitate carrying the assembled first and second assembly boxes, handles are fixedly connected to the same side of the outer walls of both the first and second assembly boxes.
[0052] This utility model provides an improved air situation information acquisition device, which has the following improvements and advantages compared with the prior art:
[0053] The device employs a first assembly box to house the air situation information acquisition component and charging power supply, and a second assembly box to house the information receiving and processing mechanism. In use, the first assembly box is disassembled, and the air situation information acquisition component and charging power supply are assembled. The charging power supply powers the assembled air situation information acquisition component and information receiving and processing mechanism. The air situation information acquisition component collects the position information of the low-altitude unmanned aerial vehicle (UAV) and sends the information to the information receiving and processing mechanism for further analysis, processing, and storage. The first and second assembly boxes are connected by bolts, and all related accessories are stored within the assembly. The device forms a neat and organized whole, facilitating transport and use in harsh environments. Attached Figure Description
[0054] To more clearly illustrate the specific embodiments of this utility model or the technical solutions in the prior art, the accompanying drawings used in the description of the specific embodiments or the prior art will be briefly explained below.
[0055] As is obvious, the accompanying drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained from these drawings without any creative effort.
[0056] Figure 1 is a schematic diagram of the structure of this utility model;
[0057] Figure 2 is a schematic diagram of the second splicing box and its structure according to the present invention;
[0058] Figure 3 is a schematic diagram of the first splicing box body and its structure according to this utility model;
[0059] Figure 4 is a schematic diagram of the screwdriver structure of this utility model;
[0060] Figure 5 is a schematic diagram of the handle assembly structure of this utility model.
[0061] Explanation of reference numerals in the attached figures:
[0062] 1-First splicing box, 11-Second storage slot, 12-Second slot, 13-Second U-shaped cover, 14-Second connecting bolt, 15-Threaded through hole, 2-Second splicing box, 21-First storage slot, 22-First slot, 23-First U-shaped cover, 24-First connecting bolt, 25-Cable outlet, 3-Pull-out shielding structure, 31-Strip groove, 32-Shielding strip, 33-Strip baffle, 4-Bolt connection structure, 41-Connecting groove, 42-Connecting plate, 43-Third connecting bolt, 5-Information receiving and processing mechanism, 51-Micro host, 52-Switch, 6-Air situation information acquisition component, 61-Sponge pad, 62-Miniature radar, 63-Antenna, 64-Connecting cable, 65-Slot, 7-Charging power supply, 8-Handle, 9-Snap-fit positioning structure, 91-Snap block, 92-Snap slot, 93 - Strip plate, 10 - Screwdriver. Detailed Implementation
[0063] The technical solution of this utility model will be clearly and completely described below with reference to the embodiments. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort are within the protection scope of this utility model.
[0064] In the description of this utility model, it should be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," and "counterclockwise," etc., indicating the orientation or positional relationship, are based on the orientation or positional relationship shown in the accompanying drawings and are only for the convenience of describing this utility model.
[0065] The description is simplified and is not intended to indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore should not be construed as a limitation of this utility model.
[0066] In the description of this utility model, it should be understood that the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of indicated technical features. Therefore, a feature defined as "first" or "second" may explicitly or implicitly include one or more of the stated features. In the description of this utility model, "a plurality of" means two or more, unless otherwise explicitly specified. Furthermore, the terms "installed," "connected," and "linked" should be interpreted broadly; for example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.
[0067] Please refer to Figures 1-5. This utility model provides the following technical solution: an air situation information acquisition device, comprising:
[0068] The first assembly box 1 has an internal cavity that houses the air situation information acquisition component 6 and the charging power supply 7.
[0069] The second splicing box 2 has an information receiving and processing mechanism 5 installed in its inner cavity;
[0070] The first splicing box 1 and the second splicing box 2 are stacked one on top of the other, and a bolt connection structure 4 is installed between the first splicing box 1 and the second splicing box 2.
[0071] When the air situation information acquisition component 6 is used in conjunction with the information receiving and processing mechanism 5, the charging power supply 7 is electrically connected to the air situation information acquisition component 6 and the information receiving and processing mechanism 5, and the air situation information acquisition component 6 and the information receiving and processing mechanism 5 are communicatively connected.
[0072] Specifically, in this embodiment, a first splicing box 1 is used to house the air situation information acquisition component 6 and the charging power supply 7, and a second splicing box 2 is used to house the information receiving and processing mechanism 5; the first splicing box 1 and the second splicing box 2 are connected by a bolt connection structure 4, and all related accessories are stored, forming a neat whole that is easy to carry and use in harsh environments;
[0073] Furthermore, when using the device, the first splicing box 1 is disassembled, the air situation information acquisition component 6 inside is taken out and assembled, and the charging power supply 7 is taken out to power the assembled air situation information acquisition component.
[0074] The information receiving and processing mechanism 5 inside component 6 and the second splicing box 2 is powered, and the position information of the low-altitude unmanned aerial vehicle is collected through the air situation information acquisition component 6. The information is then sent to the information receiving and processing mechanism 5 for analysis, processing and storage.
[0075] More specifically, the first and second modular boxes 1 and 2 have the same length and width, and they are stacked together to make them easier to carry. The height of the first and second modular boxes 1 and 2 is designed to accommodate different storage accessories.
[0076] Understandably, both the first and second assembly boxes 1 and 2 are made of wear-resistant and waterproof materials or have their surfaces covered with wear-resistant and waterproof materials, making them easy to carry and use in harsh outdoor environments.
[0077] In some embodiments, the second splicing box 2 includes:
[0078] The first storage trough 21 has a first slot 22 in the middle of its left and right side walls;
[0079] The first U-shaped cover 23 has its two ends inserted into the first slots 22 on both sides respectively;
[0080] The lower edge of the outer wall of the first slot 22 is provided with a first reserved screw hole evenly distributed along the length direction;
[0081] The first connecting bolts pass through the first pre-drilled screw holes at the lower edges of the outer walls at both ends of the first U-shaped cover 23.
[0082] 24, its end is screwed into the corresponding first reserved screw hole;
[0083] The outer wall of the first storage tank 21 has a cable outlet hole 25 corresponding to the interface of the information receiving and processing mechanism 5;
[0084] The outer wall of the first storage slot 21 is equipped with a pull-out shielding structure 3 on the side wall where the cable outlet 25 is located;
[0085] The outer wall of the first storage tank 21 is evenly distributed with fish-scale heat dissipation holes.
[0086] Specifically in this embodiment, the two ends of the first U-shaped cover 23 are fixed in the first reserved screw holes on the first slot 22 on the outer wall of the first storage groove 21 by the first connecting bolts 24. When it needs to be disassembled, all the first connecting bolts 24 can be removed.
[0087] Furthermore, there is at least one first connecting bolt 24 and a corresponding first reserved screw hole on each side to ensure the strength of the connection and fixation;
[0088] More specifically, the outlet hole 25 is used for the connection cable 64 of the air situation information acquisition component 6 to pass through, so as to facilitate the communication connection between the air situation information acquisition component 6 and the information receiving and processing mechanism 5;
[0089] Understandably, the fish-scale heat dissipation holes on the outer wall of the first storage tank 21 are used for information receiving and processing.
[0090] The heat dissipation of mechanism 5 is designed with fish scale-shaped heat dissipation holes to effectively prevent falling impurities from directly entering the first storage tank 21 during outdoor transport, and to prevent items such as grass leaves and branches from passing through the heat dissipation holes into the first storage tank 21.
[0091] In some embodiments, the pull-out blocking structure 3 includes:
[0092] A strip-shaped groove 31 is formed on the side wall of the outer wall of the first storage groove 21 where the wire outlet hole 25 is located, and the strip-shaped groove 31 has an opening on one side;
[0093] A baffle strip 32 is uniformly fixedly mounted on the front side of the inner wall of the strip groove 31 along the length direction;
[0094] A strip-shaped baffle 33 is slidably inserted between the strip-shaped groove 31 and the rear wall of the baffle 32.
[0095] Specifically, in this embodiment, a pull-out strip baffle 33 is used to block the cable outlet hole 25 on the outer wall of the first storage tank 21, preventing impurities and foreign objects from passing through the cable outlet hole 25 and entering the first storage tank 21 when carrying it; when using the device, simply pull out the strip baffle 33 to expose the cable outlet hole 25.
[0096] Furthermore, on the side of the interface of the information receiving and processing mechanism 5, near the cable outlet hole 25 on the outer wall of the first storage tank 21, the connectors of the connecting cable 64 and the charging power supply 7 can be connected to the interface of the information receiving and processing mechanism 5 by passing through the cable outlet hole 25.
[0097] More specifically, the width of the gap between the strip groove 31 and the rear wall of the shielding strip 32 is the same as the thickness of the strip baffle 33. The strip baffle 33 is inserted into this gap with an interference fit to prevent the strip baffle 33 from coming out when carried and used.
[0098] It is understandable that the cable outlet 25 is located in the gap of the shielding strip 32, and the shielding strip 32 will not obstruct the use of the cable outlet 25.
[0099] In some embodiments, a snap-fit positioning structure 9 is fitted between the bottom surface of the inner cavity of the first storage groove 21 and the information receiving and processing mechanism 5;
[0100] Strip plate 93 is fixedly assembled to the bottom surface of the inner cavity of the first storage tank 21;
[0101] A slot 92 is provided on the upper edge of the outer wall of the strip plate 93 near the information receiving and processing mechanism 5;
[0102] The information receiving and processing mechanism 5 has a card block 91 fixedly mounted on the corresponding card slot 92 on its outer wall, and the card block 91 is inserted into the corresponding card slot 92.
[0103] Specifically, in this embodiment, the card block 91 on the outer wall of the information receiving and processing mechanism 5 is engaged with the first receiving...
[0104] The information receiving and processing mechanism 5 is positioned within the cavity of the first storage tank 21 by the slot 92 on the flat plate 93 at the bottom of the inner cavity of the storage tank 21.
[0105] It is understandable that the card block 91 and the card slot 92 are in an interference fit relationship to ensure sufficient strength when they are engaged.
[0106] In some embodiments, the information receiving and processing unit 5 includes:
[0107] The switch 52 and the micro-host 51 are connected for communication.
[0108] There are three parallel strips 93, and the switch 52 and the micro-host 51 are located in the gap between adjacent strips 93;
[0109] The outer walls of the switch 52 and the micro-host 51 are fixedly fitted with card blocks 91 corresponding to the card slots 92 of the adjacent strip plates 93.
[0110] Specifically, in this embodiment, the switch 52 and the microcomputer 51 are arranged in one of the three strip panels 93.
[0111] Between them, the card block 91 on the outer wall of the switch 52 and the micro host 51 is engaged in the card slot 92 of the adjacent strip plate 93;
[0112] Furthermore, the switch 52 is used to connect the air situation information acquisition component 6 to receive and transmit the acquired data. The switch 52 transmits the received information to the micro-host 51 for processing, and uses a hard disk installed in the micro-host 51 to store the acquired and processed information, so as to facilitate the subsequent reading of the data under suitable conditions.
[0113] In some embodiments, the first splicing box 1 includes:
[0114] The second storage trough 11 has a second slot 12 opened in the middle of its left and right side walls;
[0115] The second U-shaped cover 13 has its two ends inserted into the second slots 12 on both sides respectively;
[0116] The second slot 12 has a second reserved screw hole evenly provided along its length on the lower edge of its outer wall;
[0117] The second connecting bolts pass through the second pre-drilled screw holes at the lower edges of the outer walls at both ends of the second U-shaped cover 13.
[0118] 14, its end is screwed into the corresponding second reserved screw hole;
[0119] The air situation information acquisition component 6 is located inside the second storage tank 11.
[0120] Specifically, in this embodiment, the second U-shaped cover 13 is connected to the second reserved screw hole on the second slot 12 of the second storage groove 11 via the second connecting bolt 14, and the air situation information acquisition component 6
[0121] Store it in the second storage compartment 11;
[0122] Furthermore, after removing all the second connecting bolts 14, the second U-shaped cover 13 can be detached from the second storage tank 11 to facilitate the removal of the accessories of the air situation information acquisition component 6 inside the second storage tank 11.
[0123] In some embodiments, the air situation information acquisition component 6 includes:
[0124] A sponge pad 61 is inserted into the second storage slot 11;
[0125] Miniature radar 62, antenna 63, and connecting cable 64;
[0126] The upper surface of the sponge pad 61 has slots 65 corresponding to the charging power supply 7, the miniature radar 62, the antenna 63 and the connecting cable 64, and the charging power supply 7, the miniature radar 62, the antenna 63 and the connecting cable 64 are inserted into the corresponding slots 65.
[0127] Antenna 63 is communicatively connected to miniature radar 62 via connecting cable 64, and antenna 63 is electrically connected to charging power supply 7 via connecting cable 64.
[0128] Specifically in this embodiment, the miniature radar 62 is a small and lightweight radar system whose main function is to determine the distance, speed and direction of a target by emitting electromagnetic waves and receiving the reflected signals. The antenna 63 is an accessory for receiving signals of the miniature radar 62 and is an application of existing technology.
[0129] Furthermore, the miniature radar 62 is connected to the switch 52 via the connecting cable 64, and the switch 52 is connected to the miniature host 51. The switch 52 is used for data transmission to improve network security. The switch 52 sends the information collected by the miniature radar 62 to the miniature host 51 for further analysis and processing.
[0130] More specifically, the micro-host 51 acts as the control center to control and configure the micro radar 62, including starting / stopping scanning and adjusting scanning parameters, thereby improving the system's flexibility and efficiency. The above operations are a direct application of existing technologies.
[0131] Understandably, the charging power supply 7, miniature radar 62, antenna 63, and connecting cable 64 are housed in the slot 65 at the top of the foam pad 61, providing protection for each device when carried and used. The side walls of the slot 65 are made of foam material to facilitate the insertion and removal of each device by fingers.
[0132] In some embodiments, the bolted connection structure 4 includes:
[0133] The connecting groove 41 is located on the upper edge of the outer wall of the first splicing box 1;
[0134] The connecting plate 42, with its corresponding connecting groove 41, is fixedly connected to the bottom edge of the second splicing box 2;
[0135] The connecting plate 42 is inserted into the connecting groove 41, and a third connecting bolt 43 is screwed between the connecting plate 42 and the bottom surface of the corresponding connecting groove 41.
[0136] Specifically, in this embodiment, when it is necessary to carry the air situation information acquisition component 6 or the information receiving and processing mechanism 5 separately, the first splicing box 1 and the second splicing box 2 can be separated after the third connecting bolt 43 is removed.
[0137] Furthermore, at least one pair of connecting grooves 41 and connecting plates 42 are provided correspondingly. In this embodiment, four pairs are provided at the four top corners of the mating surfaces of the first splicing box 1 and the second splicing box 2.
[0138] In some embodiments, the outer wall of the second storage groove 11 is provided with a threaded through hole 15, and the side wall of the sponge pad 61 is provided with a blind hole corresponding to the threaded through hole 15.
[0139] The blind hole of the sponge pad 61 is not connected to the slot 65;
[0140] A screwdriver 10 is screwed into the threaded through hole 15, and its tip is inserted into the blind hole of the sponge pad 61.
[0141] Specifically, in this embodiment, the first connecting bolt 24, the second connecting bolt 14, and the third connecting bolt 43 are all countersunk hexagon socket head cap screws, and the screwdriver 10 is an internal hexagon screwdriver that matches the specifications of the first connecting bolt 24, the second connecting bolt 14, and the third connecting bolt 43.
[0142] Furthermore, the screwdriver 10 has an external thread on its outer wall and is screwed into the threaded through hole 15 on the outer wall of the two storage slots 11 for storage.
[0143] Understandably, the tip of the screwdriver 10 is housed in the blind hole of the pad 61 to avoid obstruction during carrying. At the same time, the length of the screwdriver 10 handle end that protrudes from the threaded through hole 15 is relatively short, reducing obstruction during carrying.
[0144] In some embodiments, handles 8 are fixedly connected to the outer walls of the first splicing box 1 and the second splicing box 2 on the same side. When the first splicing box 1 and the second splicing box 2 are spliced, the handles 8 on both sides are grasped for carrying. When the first splicing box 1 and the second splicing box 2 are disassembled, the handles 8 of each are grasped for carrying.
[0145] Finally, it should be noted that the above embodiments are only used to illustrate the technical solution of this utility model.
[0146] This is not intended to limit the scope of the present invention. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some or all of the technical features therein. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the scope of the technical solutions of the embodiments of the present invention.
Claims
1. An air situation information acquisition device, characterized in that, include: The first splicing box (1) has an internal cavity that houses the air situation information acquisition component (6) and the charging power supply (7). The second splicing box (2) has an information receiving and processing mechanism (5) installed in its inner cavity; The first splicing box (1) and the second splicing box (2) are stacked on top of each other, and a bolt connection structure (4) is installed between the first splicing box (1) and the second splicing box (2). When the air situation information acquisition component (6) is used in conjunction with the information receiving and processing mechanism (5), the charging power supply (7) is electrically connected to the air situation information acquisition component (6) and the information receiving and processing mechanism (5), and the air situation information acquisition component (6) and the information receiving and processing mechanism (5) are communicatively connected.
2. The air information collection device according to claim 1, wherein The second assembly box (2) includes: The first storage trough (21) has a first slot (22) in the middle of its left and right side walls. The first U-shaped cover (23) has its two ends inserted into the first slots (22) on both sides respectively; The lower edge of the outer wall of the first slot (22) is provided with a first reserved screw hole evenly along the length direction; The lower edge of the outer wall at both ends of the first U-shaped cover (23) is provided with a first connecting bolt (24) through the first reserved screw hole, and its end is screwed into the corresponding first reserved screw hole; The outer wall of the first storage tank (21) has a cable outlet hole (25) corresponding to the interface of the information receiving and processing mechanism (5). The outer wall of the first storage slot (21) is equipped with a pull-out shielding structure (3) where the wire outlet hole (25) is located. The outer wall of the first storage tank (21) is evenly distributed with fish scale heat dissipation holes.
3. The air situation information acquisition device according to claim 2, characterized in that, The pull-out shielding structure (3) includes: The strip-shaped groove (31) is formed at the wire outlet hole (25) on the outer wall of the first receiving groove (21). On the side wall, the strip groove (31) has an opening on one side; A shielding strip (32) is uniformly fixedly assembled on the front side of the inner wall of the strip groove (31) along the length direction. A strip baffle (33) is slidably inserted between the strip groove (31) and the rear wall of the shielding strip (32).
4. The air information collection device according to claim 2, wherein A snap-fit positioning structure (9) is installed between the bottom surface of the inner cavity of the first storage slot (21) and the information receiving and processing mechanism (5). A strip plate (93) is fixedly assembled to the bottom surface of the inner cavity of the first storage tank (21); The outer wall of the strip plate (93) has a slot (92) on the upper edge of the side near the information receiving and processing mechanism (5); The information receiving and processing mechanism (5) has a card block (91) fixedly mounted on the outer wall corresponding to the card slot (92), and the card block (91) is inserted into the corresponding card slot (92).
5. The air quality information collection device according to claim 4, wherein The information receiving and processing unit (5) includes: The switch (52) and the microcomputer (51) are connected in communication. There are three parallel strips (93), and the switch (52) and the micro-host (51) are located in the gap between adjacent strips (93); The outer walls of the switch (52) and the micro-host (51) are fixedly fitted with card blocks (91) corresponding to the card slots (92) of the adjacent strip plate (93).
6. The air information collection device according to claim 1, wherein The first splicing box (1) includes: The second storage trough (11) has a second slot (12) in the middle of its left and right side walls. The second U-shaped cover (13) is inserted into the second slots (12) on both sides at both ends; The second slot (12) has a second reserved screw hole evenly provided along the length direction on the lower edge of its outer wall; The second connecting bolt (14) passes through the second reserved screw hole at the lower edge of the outer wall at both ends of the second U-shaped cover (13), and its end is screwed into the corresponding second reserved screw hole; The air situation information acquisition component (6) is located inside the second storage tank (11).
7. The air quality information collection device according to claim 6, wherein The air situation information acquisition component (6) includes: A sponge pad (61) is inserted into the second storage slot (11); Miniature radar (62), antenna (63) and connecting cable (64); The upper surface of the sponge pad (61) is provided with slots (65) corresponding to the charging power supply (7), the miniature radar (62), the antenna (63) and the connecting cable (64), and the charging power supply (7), the miniature radar (62), the antenna (63) and the connecting cable (64) are inserted into the corresponding slots (65); The antenna (63) is communicatively connected to the miniature radar (62) via a connecting cable (64), and the antenna (63) is electrically connected to the charging power supply (7) via the connecting cable (64).
8. The air situation information acquisition device according to claim 1, characterized in that, The bolted connection structure (4) includes: A connecting groove (41) is provided on the upper edge of the outer wall of the first splicing box (1); The connecting plate (42) and its corresponding connecting groove (41) are fixedly connected to the bottom edge of the second splicing box (2); The connecting plate (42) is inserted into the connecting groove (41), and a third connecting bolt (43) is screwed between the connecting plate (42) and the bottom surface of the corresponding connecting groove (41).
9. The air quality information collection device of claim 7, wherein, The second storage tank (11) has a threaded through hole (15) on its outer wall, and the sponge pad (61) has a blind hole on its side wall corresponding to the threaded through hole (15); The blind hole of the sponge pad (61) is not connected to the slot (65); A screwdriver (10) is screwed into the threaded through hole (15), and its tip is inserted into the blind hole of the sponge pad (61).
10. The air quality information collection device of claim 1, wherein, Handles (8) are fixedly connected to the outer walls of the first splicing box (1) and the second splicing box (2) on the same side.